Your search keyword '"electrode array"' showing total 4,226 results

1. GABAergic Inhibition Controls Receptive Field Size, Sensitivity, and Contrast Preference of Direction Selective Retinal Ganglion Cells Near the Threshold of Vision

Author

Roy, Suva, Yao, Xiaoyang, Rathinavelu, Jay, and Field, Greg D

Subjects

Biomedical and Clinical Sciences, Ophthalmology and Optometry, Eye Disease and Disorders of Vision, Neurosciences, Retinal Ganglion Cells, Gap Junctions, Inhibition, Psychological, Motion, gamma-Aminobutyric Acid, adaptation, electrode array, retina, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Information about motion is encoded by direction-selective retinal ganglion cells (DSGCs). These cells reliably transmit this information across a broad range of light levels, spanning moonlight to sunlight. Previous work indicates that adaptation to low light levels causes heterogeneous changes to the direction tuning of ON-OFF (oo)DSGCs and suggests that superior-preferring ON-OFF DSGCs (s-DSGCs) are biased toward detecting stimuli rather than precisely signaling direction. Using a large-scale multielectrode array, we measured the absolute sensitivity of ooDSGCs and found that s-DSGCs are 10-fold more sensitive to dim flashes of light than other ooDSGCs. We measured their receptive field (RF) sizes and found that s-DSGCs also have larger receptive fields than other ooDSGCs; however, the size difference does not fully explain the sensitivity difference. Using a conditional knock-out of gap junctions and pharmacological manipulations, we demonstrate that GABA-mediated inhibition contributes to the difference in absolute sensitivity and receptive field size at low light levels, while the connexin36-mediated gap junction coupling plays a minor role. We further show that under scotopic conditions, ooDSGCs exhibit only an ON response, but pharmacologically removing GABA-mediated inhibition unmasks an OFF response. These results reveal that GABAergic inhibition controls and differentially modulates the responses of ooDSGCs under scotopic conditions.

Published

2024

2. Vertical Microfluidic Trapping System for Capturing and Simultaneous Electrochemical Detection of Cells †.

Author

Bató, Lilia and Fürjes, Péter

Subjects

*ELECTRIC batteries, *CELL suspensions, *PRINTED circuits, *IMPEDANCE spectroscopy, *CELL populations

Abstract

Electrochemical impedance spectroscopy (EIS) is a non-invasive and label-free method widely used for characterizing cell cultures and monitoring their structure, behavior, proliferation and viability. Microfluidic systems are often used in combination with EIS methods utilizing small dimensions, controllable physicochemical microenvironments and offering rapid real-time measurements. In this work, an electrode array capable of conducting EIS measurements was integrated into a multichannel microfluidic chip which is able to trap individual cells or cell populations in specially designed channels comparable to the size of cells. An application-specific printed circuit board (PCB) was designed for the implementation of the impedance measurement in order to facilitate connection with the device used for taking EIS spectra and for selecting the channels to be measured. The PCB was designed in consideration of the optical screening of trapped cells in parallel with the EIS measurements which allows the comparison of EIS data with optical signals. With continuous EIS measurement, the filling of channels with cell suspension can be followed. Yeast cells were trapped in the microfluidic system and EIS spectra were recorded considering each individual channel, which allows differentiating between the number of trapped cells. [ABSTRACT FROM AUTHOR]

Published

2024

3. Estimation of outer-wall length in optimizing cochlear implantation in malformed inner ears

Author

Afrah Alshalan, Yassin Abdelsamad, Asma Alahmadi, Francesco Santoro, Salman Alhabib, Fida Almuhawas, Farid Alzhrani, Abdulrahman Alsanosi, and Anandhan Dhanasingh

Subjects

Cochlear implant, Inner ear malformation, Outer wall length, Electrode array, Cochlear parameters, Medicine, Science

Abstract

Abstract Estimation of cochlear length is gaining attention in the field of cochlear implants (CIs), mainly for selecting of CI electrode lengths. The currently available tools to estimate the cochlear duct length (CDL) are only valid for normal inner anatomy. However, inner ear malformation (IEM) types are associated with different degrees of cystic apices, limiting the application of CDL equations of normal anatomy inner ear. Therefore, this study aimed to understand the degree to which the outer wall (OW) is observed in different malformation types and to formulate mathematical equations to estimate the OW length (OWL) from cochlear parameters, namely the basal turn diameter (A-value) and width (B-value). Three-dimensional (3D) segmentation of promontory and fluid parts of the inner ear was performed to understand the extent to which the OW is visible to measure the OWL manually. Enlarged vestibular aqueduct syndrome (EVAS) was diagnosed in 37 ears, which consistently showed the extent of the OW to an angular depth of 540°, beyond which the cystic apex starts. Incomplete partition (IP) type I was observed in 30 ears, with the OW extending to only 360° of angular depth. IP type II was observed in 35 ears, with the OW extending to 450° of angular depth. IP type III was identified in 24 ears, with the OW observed for 540° of angular depth. Cavity-type malformations were observed in 36 ears, and circumference was measured in the axial view. A strong positive linear correlation was observed between the manually measured OWL and cochlear parameters for all malformation types analyzed. A multiple linear regression model was applied to formulate mathematical equations, which was further used to create a software application for estimating OWLs in IEM types, using cochlear parameters as inputs.

Published

2024

4. The role of pressure and friction forces in automated insertion of cochlear implants.

Author

Fröhlich, Max, Deutz, Jaro, Wangenheim, Matthias, Rau, Thomas S., Lenarz, Thomas, Kral, Andrej, and Schurzig, Daniel

Subjects

SODIUM dodecyl sulfate, SURGICAL robots, FRICTION, VISCOSITY, HYDRODYNAMICS, COCHLEAR implants

Abstract

Objectives: Despite the success of cochlear implant (CI) surgery for hearing restoration, reducing CI electrode insertion forces is an ongoing challenge with the goal to further reduce post-implantation hearing loss. While research in this field shows that both friction and quasistatic pressure forces occur during CI insertion, there is a lack of studies distinguishing between these origins. The present study was conducted to analyze the contribution of both force phenomena during automated CI insertion. Methods: Five MED-EL FLEX28 CI electrode arrays were inserted into both a regular and uncoiled version of the same average scala tympani (ST). Both ST models had a pressure release hole at the apical end, which was kept open or closed to quantify pressure forces. ST models were filled with different sodium dodecyl sulfate (SDS) lubricants (1, 5, and 10% SDS, water). The viscosity of lubricants was determined using a rheometer. Insertions were conducted with velocities ranging from v= 0.125 mm/s to 2.0 mm/s. Results: Viscosity of SDS lubricants at 20°C was 1.28, 1.96, and 2.51 mPas for 1, 5, and 10% SDS, respectively, which lies within the values reported for human perilymph. In the uncoiled ST model, forces remained within the noise floor (maximum: 0.049 × 10-3 N ± 1.5 × 10-3 N), indicating minimal contribution from quasistatic pressure. Conversely, forces using the regular, coiled ST model were at least an order of magnitude larger (minimum: Fmax = 28.95 × 10-3 N, v = 1 mm/s, 10% SDS), confirming that friction forces are the main contributor to total insertion forces. An N-way ANOVA revealed that both lubricant viscosity and insertion speed significantly reduce insertion forces (p < 0.001). Conclusion: For the first time, this study demonstrates that at realistic perilymph viscosities, quasistatic pressure forces minimally affect the total insertion force profile during insertion. Mixed friction is the main determinant, and significantly decreases with increaseing insertion speeds. This suggests that in clinical settings with similar ST geometries and surgical preparation, quasistatic pressure plays a subordinate role. Moreover, the findings indicate that managing the hydrodynamics of the cochlear environment, possibly through pre-surgical preparation or the use of specific lubricants, could effectively reduce insertion forces. [ABSTRACT FROM AUTHOR]

Published

2024

5. Bioimpedance sensor array for monitoring chronic wounds: Validation of method feasibility.

Author

Antoszewska, Magdalena, Spychalski, Piotr, Kekonen, Atte, Viik, Jari, and Barańska‐Rybak, Wioletta

Subjects

PATIENT monitoring equipment, WOUND healing, ULCERS, RESEARCH funding, SCIENTIFIC observation, BIOELECTRIC impedance, DESCRIPTIVE statistics, TRAUMATOLOGY diagnosis, WOUND care, CHRONIC wounds & injuries

Abstract

In an ageing society, the incidence of hard‐to‐heal wounds is rising. Chronic wound healing is a complex process, which requires specialised treatment. Clinical assessment of the wound is essential to establish care approaches but is usually based on visual evaluation and it remains challenging. Therefore, innovative quantitative methods for the assessment of chronic wounds are needed. We conducted a single‐centre observational study designed to assess the feasibility of a bioimpedance measurement method conducted with a multielectrode sensor array to monitor the wound healing process in patients with chronic wounds of venous, mixed venous–arterial and diabetic aetiology. In total, 104 measurements of bioimpedance were conducted in 18 ulcers during the study. Across all 7 patients analysed, the bioimpedance of the ulcers was consistently increasing as the wound surface was decreasing. The variables had significant (p < 0.001) and strong negative correlation (r = −0.86). We validated the feasibility of the bioimpedance measurement method for the monitoring of the wound healing process on the lower legs. It may be a promising quantitative method for monitoring the status of the wounds. However, long‐term measurements are needed to show the usability of the electrode dressing and bioimpedance measurement in the assessment of chronic wounds. [ABSTRACT FROM AUTHOR]

Published

2024

6. Microarray-Based Electrochemical Biosensing

Author

Ino, Kosuke, Utagawa, Yoshinobu, Shiku, Hitoshi, Scheper, Thomas, Editorial Board Member, Belkin, Shimshon, Editorial Board Member, Bley, Thomas, Editorial Board Member, Bohlmann, Jörg, Editorial Board Member, Gu, Man Bock, Editorial Board Member, Hu, Wei Shou, Editorial Board Member, Mattiasson, Bo, Editorial Board Member, Olsson, Lisbeth, Editorial Board Member, Seitz, Harald, Editorial Board Member, Silva, Ana Catarina, Editorial Board Member, Ulber, Roland, Series Editor, Zeng, An-Ping, Editorial Board Member, Zhong, Jian-Jiang, Editorial Board Member, Zhou, Weichang, Editorial Board Member, Bühler, Katja, Editorial Board Member, Lavrentieva, Antonina, Editorial Board Member, Lisdat, Fred, editor, and Plumeré, Nicolas, editor

Published

2024

7. The flow of axonal information among hippocampal sub-regions 2: patterned stimulation sharpens routing of information transmission.

Author

Lassers, Samuel, Vakilna, Yash, Tang, William, and Brewer, Gregory

Subjects

CA1, CA3, dentate, electrode array, entorhinal, hippocampus, networks, neural circuits, Reproducibility of Results, Hippocampus, Axons, Cerebral Cortex, Neurons

Abstract

The sub-regions of the hippocampal formation are essential for episodic learning and memory formation, yet the spike dynamics of each region contributing to this function are poorly understood, in part because of a lack of access to the inter-regional communicating axons. Here, we reconstructed hippocampal networks confined to four subcompartments in 2D cultures on a multi-electrode array that monitors individual communicating axons. In our novel device, somal, and axonal activity was measured simultaneously with the ability to ascertain the direction and speed of information transmission. Each sub-region and inter-regional axons had unique power-law spiking dynamics, indicating differences in computational functions, with abundant axonal feedback. After stimulation, spiking, and burst rates decreased in all sub-regions, spikes per burst generally decreased, intraburst spike rates increased, and burst duration decreased, which were specific for each sub-region. These changes in spiking dynamics post-stimulation were found to occupy a narrow range, consistent with the maintenance of the network at a critical state. Functional connections between the sub-region neurons and communicating axons in our device revealed homeostatic network routing strategies post-stimulation in which spontaneous feedback activity was selectively decreased and balanced by decreased feed-forward activity. Post-stimulation, the number of functional connections per array decreased, but the reliability of those connections increased. The networks maintained a balance in spiking and bursting dynamics in response to stimulation and sharpened network routing. These plastic characteristics of the network revealed the dynamic architecture of hippocampal computations in response to stimulation by selective routing on a spatiotemporal scale in single axons.

Published

2023

8. Multi Electrode Differential Voltage Sensor Based on Electric Field Coupling.

Author

Tan, Xiangyu, Xu, Xiaowei, Ao, Gang, Yang, Yonglong, and Zhang, Wenbin

Subjects

*ELECTRIC field strength, *ELECTRIC interference, *ELECTRIC potential measurement, *ELECTRIC fields, *ELECTRIC power distribution grids, *LOW voltage systems

Abstract

With the increasing demand for electricity, voltage measurement has been applied in various fields of the power grid, especially in low-voltage distribution networks and household appliances. However, in low-voltage distribution networks, traditional contact measurement cannot be used due to technical limitations such as the need to damage the insulation layer. Non contact voltage measurement is becoming the main voltage measurement method, A major technical challenge in non-contact measurement is the interference of external electric fields. In order to solve the above problems, this article develops a new type of non-contact low-voltage measurement equipment, which can overcome the interference of external electric fields on measurement and achieve high-precision non-contact voltage measurement. The experimental results indicate that the sensor designed in this paper has high measurement accuracy. The ratio error at power frequency is within ± 0.9%, and the phase error is within 3°. In addition, the sensor also has the advantages of low cost, small size, and convenient manufacturing. [ABSTRACT FROM AUTHOR]

Published

2024

9. Electrochemical Biosensor Arrays for Multiple Analyte Detection.

Author

Sen, Debashis and Lazenby, Robert A.

Abstract

The simultaneous detection of multiple analytes using electrochemical biosensor arrays has demonstrated significant potential in various fields, including medical diagnostics. These platforms are designed to be low‐cost, easy to use, and offer fast detection of a range of molecules. This concept article discusses the components necessary to achieve multiplexing with electrochemical biosensor arrays. The various methods used to fabricate electrode arrays of different types are discussed. Furthermore, the methods for the selective immobilization of multiple different bioreceptors onto individual electrodes within the array, a crucial step essential for conferring specificity to the analytical processes, are presented with relevant examples. We have focused on enzymes, antibodies and aptamers as examples of bioreceptors that have been deployed in various multianalyte electrochemical detection platforms. Finally, we discuss the key challenges associated with their application for the analysis of real samples and provide a future outlook on possible strategies that can be used to overcome these challenges. [ABSTRACT FROM AUTHOR]

Published

2024

10. Development of Automated Tool for Electrode Array Insertion and its Study on Intracochlear Pressure.

Author

Zagabathuni, Aparna, Padi, Kishore Kumar, Kameswaran, Mohan, and Subramani, Kanagaraj

Abstract

Cochlear implantation is the most successful approach for people with profound sensorineural hearing loss. Manual insertion of the electrode array may result in damaging the soft tissue structures and basilar membrane. An automated electrode array insertion device is reported to be less traumatic in cochlear implant surgery. Objectives: The present work develops a simple, reliable, and compact device for automatically inserting the electrode array during cochlear implantation and test the device to observe intracochlear pressure during simulated electrode insertion. Methods: The device actuates the electrode array by a roller mechanism. For testing the automated device, a straight cochlea having the dimension of the scala tympani and a model electrode is developed using a 3D printer. A pressure sensor is utilized to observe the pressure change at different insertional conditions. Results: The electrode is inserted into a prototype cochlea at different speeds without any pause, and it is noticed that the pressure is increased with the depth of insertion of the electrode irrespective of the speed of electrode insertion. The rate of pressure change is observed to be increased exponentially with the speed of insertion. Conclusion: At an insertion speed of 0.15 mm/s, the peak pressure is observed to be 133 Pa, which can be further evaluated in anatomical models for clinical scenarios. Level of Evidence: N/A Laryngoscope, 134:1388–1395, 2024 [ABSTRACT FROM AUTHOR]

Published

2024

11. The role of pressure and friction forces in automated insertion of cochlear implants

Author

Max Fröhlich, Jaro Deutz, Matthias Wangenheim, Thomas S. Rau, Thomas Lenarz, Andrej Kral, and Daniel Schurzig

Subjects

cochlear implant, insertion force, pressure, friction, electrode array, insertion speed, Neurology. Diseases of the nervous system, RC346-429

Abstract

ObjectivesDespite the success of cochlear implant (CI) surgery for hearing restoration, reducing CI electrode insertion forces is an ongoing challenge with the goal to further reduce post-implantation hearing loss. While research in this field shows that both friction and quasistatic pressure forces occur during CI insertion, there is a lack of studies distinguishing between these origins. The present study was conducted to analyze the contribution of both force phenomena during automated CI insertion.MethodsFive MED-EL FLEX28 CI electrode arrays were inserted into both a regular and uncoiled version of the same average scala tympani (ST). Both ST models had a pressure release hole at the apical end, which was kept open or closed to quantify pressure forces. ST models were filled with different sodium dodecyl sulfate (SDS) lubricants (1, 5, and 10% SDS, water). The viscosity of lubricants was determined using a rheometer. Insertions were conducted with velocities ranging from v= 0.125 mm/s to 2.0 mm/s.ResultsViscosity of SDS lubricants at 20°C was 1.28, 1.96, and 2.51 mPas for 1, 5, and 10% SDS, respectively, which lies within the values reported for human perilymph. In the uncoiled ST model, forces remained within the noise floor (maximum: 0.049 × 10−3 N ± 1.5 × 10−3 N), indicating minimal contribution from quasistatic pressure. Conversely, forces using the regular, coiled ST model were at least an order of magnitude larger (minimum: Fmax = 28.95 × 10−3 N, v = 1 mm/s, 10% SDS), confirming that friction forces are the main contributor to total insertion forces. An N-way ANOVA revealed that both lubricant viscosity and insertion speed significantly reduce insertion forces (p

Published

2024

12. BAYESIAN METHODS AND POLYNOMIAL CHAOS: APPLICATION TO FINDING CARDIAC BIDOMAIN PARAMETERS.

Author

KAMALAKKANNAN, ABBISH

Subjects

*CONDUCTIVITY of electrolytes, *INTRACELLULAR space, *VENTRICULAR fibrillation, *MYOCARDIAL ischemia, *INVERSE problems, *POLYNOMIAL chaos

Abstract

This article discusses the use of Bayesian methods and polynomial chaos in finding cardiac bidomain parameters for electrophysiological simulations of ventricular cardiac tissue. The article highlights the challenges in accurately determining the electrical properties of cardiac tissue and proposes a novel protocol that combines Bayesian inference techniques and polynomial chaos to retrieve these parameters from experimental measurements. The protocol is designed to account for outliers in the data and can incorporate multiple datasets obtained from different current application electrodes. The article presents results from simulated datasets and experimental measurements, demonstrating the protocol's ability to accurately infer certain parameters. However, further research is needed to improve the quality and consistency of experimental measurements for more accurate parameter retrieval. [Extracted from the article]

Published

2024

13. Vertical Microfluidic Trapping System for Capturing and Simultaneous Electrochemical Detection of Cells

Author

Lilia Bató and Péter Fürjes

Subjects

microfluidics, electrode array, EIS, cell trapping, Chemical technology, TP1-1185

Abstract

Electrochemical impedance spectroscopy (EIS) is a non-invasive and label-free method widely used for characterizing cell cultures and monitoring their structure, behavior, proliferation and viability. Microfluidic systems are often used in combination with EIS methods utilizing small dimensions, controllable physicochemical microenvironments and offering rapid real-time measurements. In this work, an electrode array capable of conducting EIS measurements was integrated into a multichannel microfluidic chip which is able to trap individual cells or cell populations in specially designed channels comparable to the size of cells. An application-specific printed circuit board (PCB) was designed for the implementation of the impedance measurement in order to facilitate connection with the device used for taking EIS spectra and for selecting the channels to be measured. The PCB was designed in consideration of the optical screening of trapped cells in parallel with the EIS measurements which allows the comparison of EIS data with optical signals. With continuous EIS measurement, the filling of channels with cell suspension can be followed. Yeast cells were trapped in the microfluidic system and EIS spectra were recorded considering each individual channel, which allows differentiating between the number of trapped cells.

Published

2024

14. A High-Performance System for Weak ECG Real-Time Detection.

Author

Xu, Kun, Yang, Yi, Li, Yu, Zhang, Yahui, and Zhang, Limin

Subjects

*ELECTROCARDIOGRAPHY, *HEART beat, *HUMAN activity recognition, *WEARABLE technology, *SYSTEMS design, *PHYSICAL activity

Abstract

Wearable devices have been widely used for the home monitoring of physical activities and healthcare conditions, among which ambulatory electrocardiogram (ECG) stands out for the diagnostic cardiovascular information it contains. Continuous and unobtrusive sensing often requires the integration of wearable sensors to existing devices such as watches, armband, headphones, etc.; nonetheless, it is difficult to detect high-quality ECG due to the nature of low signal amplitude at these areas. In this paper, a high-performance system with multi-channel signal superposition for weak ECG real-time detection is proposed. Firstly, theoretical analysis and simulation is performed to demonstrate the effectiveness of this system design. The detection system, including electrode array, acquisition board, and the application (APP), is then developed and the electrical characteristics are measured. A common mode rejection ratio (CMRR) of up to 100 dB and input inferred voltage noise below 1 μV are realized. Finally, the technique is implemented in form of ear-worn and armband devices, achieving an SNR over 20 dB. Results are also compared with the simultaneous recording of standard lead I ECG. The correlation between the heart rates derived from experimental and standard signals is higher than 0.99, showing the feasibility of the proposed technique. [ABSTRACT FROM AUTHOR]

Published

2024

15. AR‐Enabled Persistent Human–Machine Interfaces via a Scalable Soft Electrode Array.

Author

Kim, Hodam, Cha, Ho‐Seung, Kim, Minseon, Lee, Yoon Jae, Yi, Hoon, Lee, Sung Hoon, Ira, Soltis, Kim, Hojoong, Im, Chang‐Hwan, and Yeo, Woon‐Hong

Subjects

*MACHINE learning, *ELECTRODES, *ELECTRONIC systems, *VIRTUAL reality, *SIGNAL-to-noise ratio, *COMPUTER graphics, *AUGMENTED reality

Abstract

Augmented reality (AR) is a computer graphics technique that creates a seamless interface between the real and virtual worlds. AR usage rapidly spreads across diverse areas, such as healthcare, education, and entertainment. Despite its immense potential, AR interface controls rely on an external joystick, a smartphone, or a fixed camera system susceptible to lighting. Here, an AR‐integrated soft wearable electronic system that detects the gestures of a subject for more intuitive, accurate, and direct control of external systems is introduced. Specifically, a soft, all‐in‐one wearable device includes a scalable electrode array and integrated wireless system to measure electromyograms for real‐time continuous recognition of hand gestures. An advanced machine learning algorithm embedded in the system enables the classification of ten different classes with an accuracy of 96.08%. Compared to the conventional rigid wearables, the multi‐channel soft wearable system offers an enhanced signal‐to‐noise ratio and consistency over multiple uses due to skin conformality. The demonstration of the AR‐integrated soft wearable system for drone control captures the potential of the platform technology to offer numerous human–machine interface opportunities for users to interact remotely with external hardware and software. [ABSTRACT FROM AUTHOR]

Published

2024

16. Robotic assistance during cochlear implantation: the rationale for consistent, controlled speed of electrode array insertion.

Author

Kashani, Rustin G., Henslee, Allan, Nelson, Rick F., and Hansen, Marlan R.

Subjects

COCHLEAR implants, ACOUSTIC stimulation, ELECTRIC stimulation, TECHNOLOGICAL innovations, ACOUSTIC nerve, INNER ear

Abstract

Cochlear implants (CI) have revolutionized the treatment of patients with severe to profound sensory hearing loss by providing a method of bypassing normal hearing to directly stimulate the auditory nerve. A further advance in the field has been the introduction of "hearing preservation" surgery, whereby the CI electrode array (EA) is carefully inserted to spare damage to the delicate anatomy and function of the cochlea. Preserving residual function of the inner ear allows patients to receive maximal benefit from the CI and to combine CI electric stimulation with acoustic hearing, offering improved postoperative speech, hearing, and quality of life outcomes. However, under the current paradigm of implant surgery, where EAs are inserted by hand, the cochlea cannot be reliably spared from damage. Robotics-assisted EA insertion is an emerging technology that may overcome fundamental human kinetic limitations that prevent consistency in achieving steady and slow EA insertion. This review begins by describing the relationship between EA insertion speed and generation of intracochlear forces and pressures. The various mechanisms by which these intracochlear forces can damage the cochlea and lead to worsened postoperative outcomes are discussed. The constraints of manual insertion technique are compared to robotics-assisted methods, followed by an overview of the current and future state of robotics-assisted EA insertion. [ABSTRACT FROM AUTHOR]

Published

2024

17. The association between electrode impedance and short-term outcomes in cochlear implant recipients of slim modiolar and slim straight electrode arrays.

Author

Mussoi, Bruna S., Meibos, Alex, Woodson, Erika, and Sydlowski, Sarah

Subjects

*COCHLEAR implants, *ACOUSTIC stimulation, *ELECTRODES, *SPEECH perception, *WORD recognition, *STANDARD deviations

Abstract

Electrode impedance measurements from cochlear implants (CI) reflect the status of the electrode array as well as the surrounding cochlear environment, and could provide a clinical index of functional changes with the CI. The goals of this study were to examine (1) the impact of electrode array type on electrode impedance, and (2) the relationship between electrode impedance and short-term hearing preservation and speech recognition outcomes. Retrospective study of 115 adult hearing preservation CI recipients of a slim modiolar or slim straight array. Common ground electrode impedances, pre- and post-operative hearing thresholds and CNC word recognition scores were retrieved. Electrode impedances were significantly higher for recipients of the straight electrode array. Within individuals, electrode impedances were stable after the first week post-activation. However, increased standard deviation of electrode impedances was associated with greater loss of low frequency hearing at initial activation, and with poorer speech recognition at 6 months post-implantation. Results demonstrate that electrode impedances depend on the type of implanted array. Findings also suggest that there may be a role for the variability in electrode impedance across electrodes as an indicator of changes in the intracochlear environment that contribute to outcomes with a CI. [ABSTRACT FROM AUTHOR]

Published

2024

18. کاربرد روش برگردان ترکیبی دادههای مقاومت الکتریکی به منظور تعیین گسترش هندسی نشت فاضلابهای شهری) مطالعه موردی شهرستان مسجد سلیمان(

Author

احمد نیامدپور

Published

2024

19. The flow of axonal information among hippocampal sub-regions 2: patterned stimulation sharpens routing of information transmission.

Author

Lassers, Samuel Brandon, Vakilna, Yash S., Tang, William C., and Brewer, Gregory J.

Subjects

AXONAL transport, HIPPOCAMPUS (Brain), EPISODIC memory, AXONS, NEURAL circuitry, NEURONS, NEURAL transmission, THETA rhythm

Abstract

The sub-regions of the hippocampal formation are essential for episodic learning and memory formation, yet the spike dynamics of each region contributing to this function are poorly understood, in part because of a lack of access to the interregional communicating axons. Here, we reconstructed hippocampal networks confined to four subcompartments in 2D cultures on a multi-electrode array that monitors individual communicating axons. In our novel device, somal, and axonal activity was measured simultaneously with the ability to ascertain the direction and speed of information transmission. Each sub-region and inter-regional axons had unique power-law spiking dynamics, indicating dierences in computational functions, with abundant axonal feedback. After stimulation, spiking, and burst rates decreased in all sub-regions, spikes per burst generally decreased, intraburst spike rates increased, and burst duration decreased, which were specific for each sub-region. These changes in spiking dynamics post-stimulation were found to occupy a narrow range, consistent with the maintenance of the network at a critical state. Functional connections between the sub-region neurons and communicating axons in our device revealed homeostatic network routing strategies post-stimulation in which spontaneous feedback activity was selectively decreased and balanced by decreased feed-forward activity. Post-stimulation, the number of functional connections per array decreased, but the reliability of those connections increased. The networks maintained a balance in spiking and bursting dynamics in response to stimulation and sharpened network routing. These plastic characteristics of the network revealed the dynamic architecture of hippocampal computations in response to stimulation by selective routing on a spatiotemporal scale in single axons. [ABSTRACT FROM AUTHOR]

Published

2023

20. Successful hearing preservation and improved subjective sound quality with the flexible 28-mm electrode array

Author

Miryam Calvino, Isabel Sánchez-Cuadrado, Elena Muñoz, Javier Gavilán, and Luis Lassaletta

Subjects

hearing preservation, electrode array, cochlear implantation, outcome assessment, cochlear implant outcomes, speech perception, Medicine

Abstract

IntroductionFlexible electrode arrays have shown to be an effective solution to ensure atraumatic insertion. However, flexible full-length electrodes are not suited for patients with smaller cochleae. Therefore, this study aimed to evaluate short-term and medium-term hearing preservation (HP) in patients with low-frequency residual hearing (LFRH) who were implanted with a flexible 28-mm electrode array and who did not meet the indication criteria for electric-acoustic stimulation (EAS).MethodsHP was determined based on the pure-tone audiogram of the implanted ear. A bisyllable sentence test was used to assess speech perception in quiet and in noise. The hearing implant sound quality index (HISQUI19) evaluated self-reported hearing quality. The tests were conducted pre- and post-operatively, at first fitting, and at 1, 3, 6, and 12 months after first fitting.ResultsAt 12 months post first fitting, 2 patients had complete HP; 4 patients had partial HP. Speech perception scores improved in all patients of the study. The mean scores on the bisyllable sentence test in noise significantly increased from 30% pre-operatively to 62% 6 months post first-fitting and to 68% 12 months post first-fitting. The mean score of the HISQUI19 improved from 40.56 (poor) pre-operatively to 72.56 (moderate) 1 month post first-fitting and to 90.29 (good) 12 months post first-fitting.ConclusionThe 28-mm flexible electrode array facilitates atraumatic surgery and HP and results in improved speech perception and subjective sound quality scores.

Published

2024

21. AR‐Enabled Persistent Human–Machine Interfaces via a Scalable Soft Electrode Array

Author

Hodam Kim, Ho‐Seung Cha, Minseon Kim, Yoon Jae Lee, Hoon Yi, Sung Hoon Lee, Soltis Ira, Hojoong Kim, Chang‐Hwan Im, and Woon‐Hong Yeo

Subjects

augmented reality, electrode array, human–machine interface, soft wearable, Science

Abstract

Abstract Augmented reality (AR) is a computer graphics technique that creates a seamless interface between the real and virtual worlds. AR usage rapidly spreads across diverse areas, such as healthcare, education, and entertainment. Despite its immense potential, AR interface controls rely on an external joystick, a smartphone, or a fixed camera system susceptible to lighting. Here, an AR‐integrated soft wearable electronic system that detects the gestures of a subject for more intuitive, accurate, and direct control of external systems is introduced. Specifically, a soft, all‐in‐one wearable device includes a scalable electrode array and integrated wireless system to measure electromyograms for real‐time continuous recognition of hand gestures. An advanced machine learning algorithm embedded in the system enables the classification of ten different classes with an accuracy of 96.08%. Compared to the conventional rigid wearables, the multi‐channel soft wearable system offers an enhanced signal‐to‐noise ratio and consistency over multiple uses due to skin conformality. The demonstration of the AR‐integrated soft wearable system for drone control captures the potential of the platform technology to offer numerous human–machine interface opportunities for users to interact remotely with external hardware and software.

Published

2024

22. Estimation of outer-wall length in optimizing cochlear implantation in malformed inner ears

Author

Alshalan, Afrah, Abdelsamad, Yassin, Alahmadi, Asma, Santoro, Francesco, Alhabib, Salman, Almuhawas, Fida, Alzhrani, Farid, Alsanosi, Abdulrahman, and Dhanasingh, Anandhan

Published

2024

23. The flow of axonal information among hippocampal sub-regions 2: patterned stimulation sharpens routing of information transmission

Author

Samuel Brandon Lassers, Yash S. Vakilna, William C. Tang, and Gregory J. Brewer

Subjects

networks, hippocampus, electrode array, entorhinal, dentate, CA3, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The sub-regions of the hippocampal formation are essential for episodic learning and memory formation, yet the spike dynamics of each region contributing to this function are poorly understood, in part because of a lack of access to the inter-regional communicating axons. Here, we reconstructed hippocampal networks confined to four subcompartments in 2D cultures on a multi-electrode array that monitors individual communicating axons. In our novel device, somal, and axonal activity was measured simultaneously with the ability to ascertain the direction and speed of information transmission. Each sub-region and inter-regional axons had unique power-law spiking dynamics, indicating differences in computational functions, with abundant axonal feedback. After stimulation, spiking, and burst rates decreased in all sub-regions, spikes per burst generally decreased, intraburst spike rates increased, and burst duration decreased, which were specific for each sub-region. These changes in spiking dynamics post-stimulation were found to occupy a narrow range, consistent with the maintenance of the network at a critical state. Functional connections between the sub-region neurons and communicating axons in our device revealed homeostatic network routing strategies post-stimulation in which spontaneous feedback activity was selectively decreased and balanced by decreased feed-forward activity. Post-stimulation, the number of functional connections per array decreased, but the reliability of those connections increased. The networks maintained a balance in spiking and bursting dynamics in response to stimulation and sharpened network routing. These plastic characteristics of the network revealed the dynamic architecture of hippocampal computations in response to stimulation by selective routing on a spatiotemporal scale in single axons.

Published

2023

24. Effect of Valinomycin on the Respiration Activity of Zebrafish Embryos Using a Large-scale-integration-based Multiple Amperometric Biosensor.

Author

Kazuki Terao, Masato Suzuki, Ryota Kunikata, Atsushi Suda, Inoue, Kumi Y., Kosuke Ino, Tomokazu Matsue, and Tomoyuki Yasukawa

Subjects

ZEBRA danio embryos, BRACHYDANIO, EMBRYOS, RESPIRATION, TOXICITY testing, BIOSENSORS, ANIMAL experimentation

Abstract

A large-scale-integration-based multiple amperometric biosensor (Bio-LSI) was used to obtain images of oxygen concentration around zebrafish embryos and monitor their respiration activity after valinomycin at different concentrations was injected. The regions with a low reduction current of oxygen coincided with the embryo positions. The reduction current decreased immediately after adding valinomycin owing to the increase in the respiration activity of the embryos. The decrement of the reduction current increased with valinomycin concentration. The estimation system is very simple because no alignment is required between the embryos and the electrodes arrayed at the bottom of the chamber. In general, the use of zebrafish embryos for toxicity tests has been expected as an alternative for animal tests. However, a relatively long time is required to estimate the mortality and morphological changes of the embryos caused by chemical substances by a standardized method. The use of the present system is expected to allow the rapid and simple sensing of the effects of chemical substances on the respiration activity of zebrafish embryos. [ABSTRACT FROM AUTHOR]

Published

2023

25. Full-array channel discrimination in cochlear implants: validation and clinical application.

Author

Windmeijer, Coen A. A., Biesheuvel, Jan Dirk, Boermans, Peter-Paul B. M., Briaire, Jeroen J., and Frijns, Johan H. M.

Subjects

*COCHLEAR implants, *PSYCHOPHYSICS, *SPEECH perception, *VOWELS, *ELECTRODES, *STATISTICS, *MUSICAL pitch, *MANN Whitney U Test, *REGRESSION analysis, *COMPARATIVE studies, *CRONBACH'S alpha, *PSYCHOMETRICS, *T-test (Statistics), *CONSONANTS, *PHONETICS, *ELECTRIC stimulation, *DESCRIPTIVE statistics, *MUSICAL perception, *DATA analysis

Abstract

We sought to validate our proposed tool for estimating channel discrimination of cochlear implant (CI) users along the full electrode array and to assess associations between place-pitch discrimination and speech perception. In two tests, participants identified one stimulus (probe) as the odd-one-out compared with two reference stimuli. Probe stimuli were evoked using dual electrode stimulation characterised by the current steering coefficient α. The first test measured psychometric functions (PFs) on pre-defined contacts, with just a noticeable difference (JNDα) as the outcome variable. The second test estimated channel discrimination on the full electrode array, yielding a discrimination score of Dα. We measured speech perception as free-field consonant-vowel-consonant phoneme recognition scores. We included 25 adults with at least 6 months of CI experience. JNDα and Dα scores measured on the same contact correlated significantly (rs = 0.64, p < 0.001). Mean JNDα and speech perception scores showed significant relationships in quiet and in noise. Dα correlated strongly with JNDα scores obtained with the PFs. For poor performers, the full-array test may underestimate JNDα. The full-array pitch discrimination test could be a helpful clinical tool, such as for fitting regions of lesser pitch discrimination ability. [ABSTRACT FROM AUTHOR]

Published

2023

26. The Flow of Axonal Information Among Hippocampal Subregions: 1. Feed-Forward and Feedback Network Spatial Dynamics Underpinning Emergent Information Processing

Author

Vakilna, Yash S, Tang, William C, Wheeler, Bruce C, and Brewer, Gregory J

Subjects

Neurosciences, Neurodegenerative, Bioengineering, Mental Health, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Animals, Artificial Intelligence, Axons, Cognition, Feedback, Hippocampus, Rats, electrode array, entorhinal, dentate, CA3, CA1, axons, burst, power law

Abstract

The tri-synaptic pathway in the mammalian hippocampus enables cognitive learning and memory. Despite decades of reports on anatomy and physiology, the functional architecture of the hippocampal network remains poorly understood in terms of the dynamics of axonal information transfer between subregions. Information inputs largely flow from the entorhinal cortex (EC) to the dentate gyrus (DG), and then are processed further in the CA3 and CA1 before returning to the EC. Here, we reconstructed elements of the rat hippocampus in a novel device over an electrode array that allowed for monitoring the directionality of individual axons between the subregions. The direction of spike propagation was determined by the transmission delay of the axons recorded between two electrodes in microfluidic tunnels. The majority of axons from the EC to the DG operated in the feed-forward direction, with other regions developing unexpectedly large proportions of feedback axons to balance excitation. Spike timing in axons between each region followed single exponential log-log distributions over two orders of magnitude from 0.01 to 1 s, indicating that conventional descriptors of mean firing rates are misleading assumptions. Most of the spiking occurred in bursts that required two exponentials to fit the distribution of inter-burst intervals. This suggested the presence of up-states and down-states in every region, with the least up-states in the DG to CA3 feed-forward axons and the CA3 subregion. The peaks of the log-normal distributions of intra-burst spike rates were similar in axons between regions with modes around 95 Hz distributed over an order of magnitude. Burst durations were also log-normally distributed around a peak of 88 ms over two orders of magnitude. Despite the diversity of these spike distributions, spike rates from individual axons were often linearly correlated to subregions. These linear relationships enabled the generation of structural connectivity graphs, not possible previously without the directional flow of axonal information. The rich axonal spike dynamics between subregions of the hippocampus reveal both constraints and broad emergent dynamics of hippocampal architecture. Knowledge of this network architecture may enable more efficient computational artificial intelligence (AI) networks, neuromorphic hardware, and stimulation and decoding from cognitive implants.

Published

2021

27. Evaluation of the Performance of OTOPLAN-Based Cochlear Implant Electrode Array Selection: A Retrospective Study.

Author

Távora-Vieira, Dayse, Voola, Marcus, Kuthubutheen, Jafri, Friedland, Peter, Gibson, Daren, and Acharya, Aanand

Subjects

*ELECTRODES, *THREE-dimensional imaging, *COCHLEAR implants, *ABSOLUTE value, *COMPUTED tomography, *SOFTWARE architecture

Abstract

Otoplan is a surgical planning software designed to assist with cochlear implant surgery. One of its outputs is a recommendation of electrode array type based on imaging parameters. In this retrospective study, we evaluated the differences in auditory outcomes between patients who were implanted with arrays corresponding to those recommended by the Otoplan software versus those in which the array selection differed from the Otoplan recommendation. Pre-operative CT images from 114 patients were imported into the software, and array recommendations were generated. These were compared to the arrays which had actually been implanted during surgery, both in terms of array type and length. As recommended, 47% of patients received the same array, 34% received a shorter array, and 18% received a longer array. For reasons relating to structure and hearing preservation, 83% received the more flexible arrays. Those who received stiffer arrays had cochlear malformations or ossification. A negative, although non-statistically significant correlation was observed between the CNC scores at 12 months and the absolute value of the difference between recommended array and implanted array. In conclusion, clinicians may be slightly biased toward shorter electrode arrays due to their perceived greater ability to achieve full insertion. Using 3D imaging during the pre-operative planning may improve clinicians' confidence to implant longer electrode arrays, where appropriate, to achieve optimum hearing outcomes. [ABSTRACT FROM AUTHOR]

Published

2023

28. One‐Year Hearing Preservation and Speech Outcomes Comparing Slim Modiolar and Lateral Wall Arrays.

Author

Zhan, Kevin Y., Walia, Amit, Durakovic, Nedim, Wick, Cameron C., Buchman, Craig A., Shew, Matthew A., and Herzog, Jacques A.

Abstract

Objective: Compare postoperative speech outcomes in hearing preservation (HP) cochlear implantation (CI) patients with a low‐frequency pure‐tone average (LFPTA) ≤ 60 dB using 2 electrode array designs. Study Design: Retrospective cohort study. Setting: Large academic cochlear implant referral center. Methods: We reviewed adult HP CI cases using either the slim modiolar electrode (SME) (CI 532/CI 632) or th slim lateral wall electrode (SLWE) (CI 624). One‐year speech outcomes and HP status were the primary outcomes. Results: A total of 132 implanted ears were analyzed (mean age 73.1 years, standard deviation [SD] 12.6), with 72% (N = 95) with CI 532/632 and 28% (N = 37) with CI 624. The mean preoperative LFPTA was 44.8 dB, SD 11.8. One‐year functional HP was 27.2% (mean LFPTA shift 46.1 dB, SD 22.1) and was as follows: SME 23.9% and SLWE 36.4%, p =.168. The mean age at implantation was significantly younger only in SLWE patients with preserved hearing (66.9 vs 80.3 years, p =.008). At 6 months, speech measures were significantly better in all outcomes in HP patients with an SLWE than nonpreserved SLWE patients; this effect abated at 1 year as performance among nonpreserved SLWE patients became equivalent to the remaining cohort. Speech outcomes in SME patients were similar regardless of HP status. Age at implantation and datalogging was correlated with speech outcomes. Conclusion: In this cohort of HP patients, a 1‐year functional HP rate of 23.9% (SME) and 36.4% (SLWE) was observed (p = 0.168). This was initially 57.1% (SME) and 70.3% (SLWE) at activation, p =.172. Datalogging and age at implantation were correlated with postoperative speech outcomes. [ABSTRACT FROM AUTHOR]

Published

2023

29. Targeted transcutaneous spinal cord stimulation promotes persistent recovery of upper limb strength and tactile sensation in spinal cord injury: a pilot study.

Author

Chandrasekaran, Santosh, Bhagat, Nikunj A., Ramdeo, Richard, Ebrahimi, Sadegh, Sharma, Pawan D., Griffin, Doug G., Stein, Adam, Harkema, Susan J., and Bouton, Chad E.

Subjects

SPINAL cord, SPINAL cord injuries, CERVICAL cord, PEOPLE with paralysis, SENSES, PILOT projects

Abstract

Long-term recovery of limb function is a significant unmet need in people with paralysis. Neuromodulation of the spinal cord through epidural stimulation, when paired with intense activity-based training, has shown promising results toward restoring volitional limb control in people with spinal cord injury. Non-invasive neuromodulation of the cervical spinal cord using transcutaneous spinal cord stimulation (tSCS) has shown similar improvements in upper-limb motor control rehabilitation. However, the motor and sensory rehabilitative effects of activating specific cervical spinal segments using tSCS have largely remained unexplored. We show in two individuals with motor-complete SCI that targeted stimulation of the cervical spinal cord resulted in up to a 1,136% increase in exerted force, with weekly activity-based training. Furthermore, this is the first study to document up to a 2-point improvement in clinical assessment of tactile sensation in SCI after receiving tSCS. Lastly, participant gains persisted after a one-month period void of stimulation, suggesting that targeted tSCS may lead to persistent recovery of motor and sensory function. [ABSTRACT FROM AUTHOR]

Published

2023

30. Evolution of Cochlear Implant Technology over the Last 35 Years

Author

Dhanasingh, Anandhan, DeSaSouza, Sandra, and DeSaSouza, Sandra, editor

Published

2022

31. Electrode Array Design and Surgical Technique in Common Cavity Deformity

Author

Dhanasingh, Anandhan and Li, Yongxin, editor

Published

2022

32. Factors Affecting Electrical Impedance Tomography: A Review

Author

Dong, Xingkun, Qin, Lei, Cheng, Xin, Huang, Shifeng, Zhou, Haijun, Ren, Hongwei, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Li, Yong, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zamboni, Walter, Series Editor, Zhang, Junjie James, Series Editor, Jing, Xingjian, editor, Ding, Hu, editor, and Wang, Jiqiang, editor

Published

2022

33. Three-dimensional finite element analysis on cochlear implantation electrode insertion.

Author

Ren, Liu-Jie, Yu, Yi, Zhang, Yu-Heng, Liu, Xin-Dong, Sun, Zeng-Jun, Yao, Wen-Juan, Zhang, Tian-Yu, Wang, Cheng, and Li, Chen-Long

Subjects

*COCHLEAR implants, *YOUNG'S modulus, *ELECTRODES, *FINITE element method

Abstract

Studying the insertion process of cochlear implant (CI) electrode array (EA) is important to ensure successful, sufficient, and safe implantation. A three-dimensional finite element (FE) model was developed to simulate the insertion process. The cochlear structures were reconstructed from an average statistical shape model (SSM) of human cochlea. The electrode is simplified as a long and tapered beam of homogeneous elastic materials, contacting and interacting with the stiff cochlear structures. A quasi-static insertion simulation was conducted, the insertion force and the contact pressure between the electrode and the cochlear wall, were calculated to evaluate the smoothness of insertion and the risk of potential cochlear trauma. Based on this model, different EA designs were analyzed, including the Young's modulus, the straight or bended shape, the normal or a more tapped section size. The influence of the insertion angle was also discussed. Our simulations indicate that reducing the EA Young's modulus, tapering and pre-bending are effective ways to ensure safe and successful EA implantation. This model is beneficial for optimizing EA designs and is potentially useful for designing patient-specific CI surgery. [ABSTRACT FROM AUTHOR]

Published

2023

34. Conformable Electrode Arrays for Wearable Neuroprostheses.

Author

RaviChandran, Narrendar, Teo, Mei Ying, McDaid, Andrew, and Aw, Kean

Subjects

*NEUROPROSTHESES, *ELECTRODES, *CARBON-black, *ELECTRIC stimulation

Abstract

Wearable electrode arrays can selectively stimulate muscle groups by modulating their shape, size, and position over a targeted region. They can potentially revolutionize personalized rehabilitation by being noninvasive and allowing easy donning and doffing. Nevertheless, users should feel comfortable using such arrays, as they are typically worn for an extended time period. Additionally, to deliver safe and selective stimulation, these arrays must be tailored to a user's physiology. Fabricating customizable electrode arrays needs a rapid and economical technique that accommodates scalability. By leveraging a multilayer screen-printing technique, this study aims to develop personalizable electrode arrays by embedding conductive materials into silicone-based elastomers. Accordingly, the conductivity of a silicone-based elastomer was altered by adding carbonaceous material. The 1:8 and 1:9 weight ratio percentages of carbon black (CB) to elastomer achieved conductivities between 0.0021–0.0030 S cm−1 and were suitable for transcutaneous stimulation. Moreover, these ratios maintained their stimulation performance after several stretching cycles of up to 200%. Thus, a soft, conformable electrode array with a customizable design was demonstrated. Lastly, the efficacy of the proposed electrode arrays to stimulate hand function tasks was evaluated by in vivo experiments. The demonstration of such arrays encourages the realization of cost-effective, wearable stimulation systems for hand function restoration. [ABSTRACT FROM AUTHOR]

Published

2023

35. Muscle innervation zone estimation from monopolar high-density M-waves using principal component analysis and radon transform.

Author

Chengjun Huang, Zhiyuan Lu, Maoqi Chen, Cliff S. Klein, Yingchun Zhang, Sheng Li, and Ping Zhou

Subjects

RADON transforms, PRINCIPAL components analysis, SKELETAL muscle, INNERVATION, BICEPS brachii, CROSS correlation

Abstract

This study examined methods for estimating the innervation zone (IZ) of a muscle using recorded monopolar high density M waves. Two IZ estimation methods based on principal component analysis (PCA) and Radon transform (RT) were examined. Experimental M waves, acquired from the biceps brachii muscles of nine healthy subjects were used as testing data sets. The performance of the two methods was evaluated by comparing their IZ estimations with manual IZ detection by experienced human operators. Compared with manual detection, the agreement rate of the estimated IZs was 83% and 63% for PCA and RT based methods, respectively, both using monopolar high density M waves. In contrast, the agreement rate was 56% for cross correlation analysis using bipolar high density M waves. The mean difference in estimated IZ location between manual detection and the tested method was 0.12 ± 0.28 inter-electrode-distance (IED) for PCA, 0.33 ± 0.41 IED for RT and 0.39 ± 0.74 IED for cross correlation-based methods. The results indicate that the PCA based method was able to automatically detect muscle IZs from monopolar M waves. Thus, PCA provides an alternative approach to estimate IZ location of voluntary or electrically-evoked muscle contractions, and may have particular value for IZ detection in patients with impaired voluntary muscle activation. [ABSTRACT FROM AUTHOR]

Published

2023

36. A High-Performance System for Weak ECG Real-Time Detection

Author

Kun Xu, Yi Yang, Yu Li, Yahui Zhang, and Limin Zhang

Subjects

ECG, noise suppression, multi-channel system, electrode array, Chemical technology, TP1-1185

Abstract

Wearable devices have been widely used for the home monitoring of physical activities and healthcare conditions, among which ambulatory electrocardiogram (ECG) stands out for the diagnostic cardiovascular information it contains. Continuous and unobtrusive sensing often requires the integration of wearable sensors to existing devices such as watches, armband, headphones, etc.; nonetheless, it is difficult to detect high-quality ECG due to the nature of low signal amplitude at these areas. In this paper, a high-performance system with multi-channel signal superposition for weak ECG real-time detection is proposed. Firstly, theoretical analysis and simulation is performed to demonstrate the effectiveness of this system design. The detection system, including electrode array, acquisition board, and the application (APP), is then developed and the electrical characteristics are measured. A common mode rejection ratio (CMRR) of up to 100 dB and input inferred voltage noise below 1 μV are realized. Finally, the technique is implemented in form of ear-worn and armband devices, achieving an SNR over 20 dB. Results are also compared with the simultaneous recording of standard lead I ECG. The correlation between the heart rates derived from experimental and standard signals is higher than 0.99, showing the feasibility of the proposed technique.

Published

2024

37. Electrochemical performance study of Ag/AgCl and Au flexible electrodes for unobtrusive monitoring of human biopotentials

Author

Jonas F. Kurniawan, Alexis B. Allegra, Timothy Pham, Andrew K. L. Nguyen, Nathan L. J. Sit, Boris Tjhia, Andrew J. Shin, and Todd P. Coleman

Subjects

biopotential, electrochemical impedance spectroscopy (EIS), electrode array, electrophysiology, flexible electronics, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract Flexible and stretchable electronics are a logical choice for the recording of biopotentials, due to their improved patient comfort and customizability. There is, however, significant variance in the signal quality received from these electrodes based on material, size, and target recording frequency. Here we develop a methodology based on Electrochemical Impedance Spectroscopy (EIS) and circuit modeling for optimizing electrodes for a specific application. We use EIS to measure the frequency dependent impedance characteristics of gold (Au) and silver/silver chloride (Ag/AgCl) electrodes of different diameters. Additionally, we use a Randles circuit model and perform model fitting with our data to extrapolate results to arbitrary frequencies and diameters. We found that at low frequencies (

Published

2022

38. A combined cuff electrode array for organ-specific selective stimulation of vagus nerve enabled by Electrical Impedance Tomography

Author

Enrico Ravagli, Jeffrey Ardell, David Holder, and Kirill Aristovich

Subjects

electrical impedance tomography, EIT, electrode array, neuromodulation, selective stimulation, vagus nerve, Medical technology, R855-855.5

Abstract

Previously developed spatially-selective Vagus Nerve Stimulation (sVNS) allows the targeting of specific nerve fascicles through current steering in a multi-electrode nerve cuff but relies on a trial-and-error strategy to identify the relative orientation between electrodes and fascicles. Fast Neural Electrical Impedance Tomography (FN-EIT) has been recently used for imaging neural traffic in the vagus nerves of pigs in a cross-correlation study with sVNS and MicroCT fascicle tracking. FN-EIT has the potential for allowing targeted sVNS; however, up to now, stimulation and imaging have been performed with separate electrode arrays. In this study, different options were evaluated in-silico to integrate EIT and stimulation into a single electrode array without affecting spatial selectivity. The original pig vagus EIT electrode array geometry was compared with a geometry integrating sVNS and EIT electrodes, and with direct use of sVNS electrodes for EIT imaging. Modelling results indicated that both new designs could achieve image quality similar to the original electrode geometry in all tested markers (e.g., co-localisation error

Published

2023

39. Acute effects of cochleostomy and electrode-array insertion on compound action potentials in normal-hearing guinea pigs.

Author

Jwair, Saad, Ramekers, Dyan, Thomeer, Hans G. X. M., and Versnel, Huib

Subjects

ACTION potentials, GUINEA pigs, ACOUSTIC stimulation, COCHLEAR implants, HAIR cells, ELECTRODES, COCHLEA

Abstract

Introduction: Electrocochleography (ECochG) is increasingly used in cochlear implant (CI) surgery, in order to monitor the effect of insertion of the electrode array aiming to preserve residual hearing. However, obtained results are often difficult to interpret. Here we aim to relate changes in ECochG responses to acute trauma induced by different stages of cochlear implantation by performing ECochG at multiple time points during the procedure in normal-hearing guinea pigs. Materials and methods: Eleven normal-hearing guinea pigs received a gold-ball electrode that was fixed in the round-window niche. ECochG recordings were performed during the four steps of cochlear implantation using the gold-ball electrode: (1) Bullostomy to expose the round window, (2) hand-drilling of 0.5- 0.6 mm cochleostomy in the basal turn near the round window, (3) insertion of a short flexible electrode array, and (4) withdrawal of electrode array. Acoustical stimuli were tones varying in frequency (0.25-16 kHz) and sound level. The ECochG signal was primarily analyzed in terms of threshold, amplitude, and latency of the compound action potential (CAP). Midmodiolar sections of the implanted cochleas were analyzed in terms of trauma to hair cells, modiolar wall, osseous spiral lamina (OSL) and lateral wall. Results: Animals were assigned to cochlear trauma categories: minimal (n = 3), moderate (n = 5), or severe (n = 3). After cochleostomy and array insertion, CAP threshold shifts increased with trauma severity. At each stage a threshold shift at high frequencies (4-16 kHz) was accompanied with a threshold shift at low frequencies (0.25-2 kHz) that was 10-20 dB smaller. Withdrawal of the array led to a further worsening of responses, which probably indicates that insertion and removal trauma affected the responses rather than the mere presence of the array. In two instances, CAP threshold shifts were considerably larger than threshold shifts of cochlear microphonics, which could be explained by neural damage due to OSL fracture. A change in amplitudes at high sound levels was strongly correlated with threshold shifts, which is relevant for clinical ECochG performed at one sound level. Conclusion: Basal trauma caused by cochleostomy and/or array insertion should be minimized in order to preserve the low-frequency residual hearing of CI recipients. [ABSTRACT FROM AUTHOR]

Published

2023

40. A Dense Conformal Electrode Array for High Spatial Resolution Stimulation of Electrosensory Systems.

Author

Kumar, Vikrant, Yu, Caroline, McGinn, Christine K., Perks, Krista E., Thompson, Sarah M., Sawtell, Nathaniel B., and Kymissis, Ioannis

Subjects

*SPATIAL resolution, *GOLD electrodes, *ELECTRIC fishes, *ELECTRODES, *SPATIAL systems

Abstract

Studies of electrosensory systems have led to insights into a number of general issues in biology. However, investigations of these systems have been limited by the inability to precisely control spatial patterns of electrosensory input. In this paper, an electrode array and a system to selectively stimulate spatially restricted regions of an electroreceptor array are presented. The array has 96 channels consisting of chrome/gold electrodes patterned on a flexible parylene‐C substrate and encapsulated with another parylene‐C layer. The conformability of the electrode array allows for optimal current driving and surface interface conditions. Recordings of neural activity at the first central processing stage in weakly electric mormyrid fish support the potential of this system for high spatial resolution stimulation and mapping of electrosensory systems. [ABSTRACT FROM AUTHOR]

Published

2023

41. Probing and monitoring multiple forms of localised corrosion occurring concurrently on pipeline steels in marine environments.

Author

Laleh, Majid, Huo, Ying, Kannan, M. Bobby, Petersen, Robert B., Melchers, Robert E., and Tan, Mike Yongjun

Subjects

*SEAWATER corrosion, *PITTING corrosion, *UNDERWATER pipelines, *STEEL corrosion, *ELECTRODES, PIPELINE corrosion

Abstract

An electrode array probe, with a novel approach, has been specifically designed to enable the in-situ field monitoring of multiple forms of localised corrosion of steel exposed to marine environments. The initiation and propagation of localised corrosion within the crevice area as well as at the steel weldment were visualised and evaluated over one-year field exposure at two different marine locations in Australia. The results show the varied initiation and propagation behaviour of crevice corrosion and weldment corrosion on steel, which provide experimental evidence for 'bi-modal' behaviour and the change-over of corrosion modes in extended periods of marine exposure. • A novel corrosion probe enables the in-situ field monitoring of localised marine corrosion. • 61-week field monitoring of three types of co-existing localised corrosion in the sea. • Localised corrosion rates were significantly higher than general marine corrosion. • Experimental evidence has been obtained showing 'bi-modal' marine corrosion behaviour. • The new probe is a promising tool for localised corrosion monitoring in the sea. [ABSTRACT FROM AUTHOR]

Published

2024

42. Audio Signal Processing for Cochlear Implants

Author

Maheswari, K. T., Baranikumar, R., Lavanya, D., Nandhakumar, A., Srinivasan, M., Ghosh, Arindam, Series Editor, Chua, Daniel, Series Editor, de Souza, Flavio Leandro, Series Editor, Aktas, Oral Cenk, Series Editor, Han, Yafang, Series Editor, Gong, Jianghong, Series Editor, Jawaid, Mohammad, Series Editor, Kumaresan, G., editor, Shanmugam, N. Siva, editor, and Dhinakaran, V., editor

Published

2021

43. The StentrodeTM Neural Interface System

Author

Opie, Nicholas, Gan, Woon-Seng, Series Editor, Kuo, C.-C. Jay, Series Editor, Zheng, Thomas Fang, Series Editor, Barni, Mauro, Series Editor, Guger, Christoph, editor, Allison, Brendan Z., editor, and Tangermann, Michael, editor

Published

2021

44. A flexible electrode array for determining regions of motor function activated by epidural spinal cord stimulation in rats with spinal cord injury

Author

Guang-Wei Mao, Jian-Jun Zhang, Hao Su, Zhi-Jun Zhou, Lin-Sen Zhu, Xiao-Ying Lü, and Zhi-Gong Wang

Subjects

electrode array, epidural spinal cord stimulation, evoked potentials, motor function, rehabilitation, spinal cord injury, spinal segment, Neurology. Diseases of the nervous system, RC346-429

Abstract

Epidural stimulation of the spinal cord is a promising technique for the recovery of motor function after spinal cord injury. The key challenges within the reconstruction of motor function for paralyzed limbs are the precise control of sites and parameters of stimulation. To activate lower-limb muscles precisely by epidural spinal cord stimulation, we proposed a high-density, flexible electrode array. We determined the regions of motor function that were activated upon epidural stimulation of the spinal cord in a rat model with complete spinal cord, which was established by a transection method. For evaluating the effect of stimulation, the evoked potentials were recorded from bilateral lower-limb muscles, including the vastus lateralis, semitendinosus, tibialis anterior, and medial gastrocnemius. To determine the appropriate stimulation sites and parameters of the lower muscles, the stimulation characteristics were studied within the regions in which motor function was activated upon spinal cord stimulation. In the vastus lateralis and medial gastrocnemius, these regions were symmetrically located at the lateral site of L1 and the medial site of L2 vertebrae segment, respectively. The tibialis anterior and semitendinosus only responded to stimulation simultaneously with other muscles. The minimum and maximum stimulation threshold currents of the vastus lateralis were higher than those of the medial gastrocnemius. Our results demonstrate the ability to identify specific stimulation sites of lower muscles using a high-density and flexible array. They also provide a reference for selecting the appropriate conditions for implantable stimulation for animal models of spinal cord injury. This study was approved by the Animal Research Committee of Southeast University, China (approval No. 20190720001) on July 20, 2019.

Published

2022

45. The ElectroUteroGraph: A Novel Tool for Assessing Uterine Contractions of Non-Pregnant Women

Author

Julius Georgiou, Konstantinos Lekkas, Giorgos Varnava, Marios Sophocleous, Andreas Michaelides, and Vasilios Tanos

Subjects

Electrode array, electromyography, non-gravid uterus, uterine electrophysiology, uterine peristalsis, Computer applications to medicine. Medical informatics, R858-859.7, Medical technology, R855-855.5

Abstract

Goal: Uterine contractility is known to play significant role in women's health. Ultrasonography and magnetic resonance imaging have been used for assessing uterine peristalsis, however they lack practicality, objectivity, and cost-effectiveness. In this paper, the ElectroUteroGraph (EUG) and novel electrodes are introduced, to cover the unmet need of practical intrauterine contractility assessment. The EUG measures biopotentials produced by uterine muscle contraction, similar to the basis of electrocardiography. Methods: The EUG was used to fifteen healthy, non-pregnant women of reproductive age. Amplitude and frequency-related features were derived from our recordings. Results: The EUG and novel electrodes did not cause any pain or discomfort to the patients, over their multiple recording sessions. The collected data showed difference between the proliferative and luteal phase of menstrual cycle (p < 0.05). Conclusions: The EUG can accurately measure uterine electrical activity, in a simple, standardized, safe and pain-free approach, leading to objective evaluation of uterine peristalsis.

Published

2022

46. Acute effects of cochleostomy and electrode-array insertion on compound action potentials in normal-hearing guinea pigs

Author

Saad Jwair, Dyan Ramekers, Hans G. X. M. Thomeer, and Huib Versnel

Subjects

electrocochleography, electrode array, cochleostomy, compound action potential, cochlear microphonics, cochlear implantation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

IntroductionElectrocochleography (ECochG) is increasingly used in cochlear implant (CI) surgery, in order to monitor the effect of insertion of the electrode array aiming to preserve residual hearing. However, obtained results are often difficult to interpret. Here we aim to relate changes in ECochG responses to acute trauma induced by different stages of cochlear implantation by performing ECochG at multiple time points during the procedure in normal-hearing guinea pigs.Materials and methodsEleven normal-hearing guinea pigs received a gold-ball electrode that was fixed in the round-window niche. ECochG recordings were performed during the four steps of cochlear implantation using the gold-ball electrode: (1) Bullostomy to expose the round window, (2) hand-drilling of 0.5–0.6 mm cochleostomy in the basal turn near the round window, (3) insertion of a short flexible electrode array, and (4) withdrawal of electrode array. Acoustical stimuli were tones varying in frequency (0.25–16 kHz) and sound level. The ECochG signal was primarily analyzed in terms of threshold, amplitude, and latency of the compound action potential (CAP). Midmodiolar sections of the implanted cochleas were analyzed in terms of trauma to hair cells, modiolar wall, osseous spiral lamina (OSL) and lateral wall.ResultsAnimals were assigned to cochlear trauma categories: minimal (n = 3), moderate (n = 5), or severe (n = 3). After cochleostomy and array insertion, CAP threshold shifts increased with trauma severity. At each stage a threshold shift at high frequencies (4–16 kHz) was accompanied with a threshold shift at low frequencies (0.25–2 kHz) that was 10–20 dB smaller. Withdrawal of the array led to a further worsening of responses, which probably indicates that insertion and removal trauma affected the responses rather than the mere presence of the array. In two instances, CAP threshold shifts were considerably larger than threshold shifts of cochlear microphonics, which could be explained by neural damage due to OSL fracture. A change in amplitudes at high sound levels was strongly correlated with threshold shifts, which is relevant for clinical ECochG performed at one sound level.ConclusionBasal trauma caused by cochleostomy and/or array insertion should be minimized in order to preserve the low-frequency residual hearing of CI recipients.

Published

2023

47. Evaluating cochlear insertion trauma and hearing preservation after cochlear implantation (CIPRES): a study protocol for a randomized single-blind controlled trial

Author

Saad Jwair, Ralf A. Boerboom, Huib Versnel, Robert J. Stokroos, and Hans G. X. M. Thomeer

Subjects

Cochlear implant, Insertion trauma, Electrode array, Lateral wall, Perimodiolar, Round window, Medicine (General), R5-920

Abstract

Abstract Background In order to preserve residual hearing in patients with sensorineural hearing loss (SNHL) who receive a cochlear implant (CI), insertion trauma to the delicate structures of the cochlea needs to be minimized. The surgical approach comprises the conventional mastoidectomy-posterior tympanotomy (MPT) to arrive at the middle ear, followed by either a cochleostomy (CO) or the round window (RW) approach. Both techniques have their benefits and disadvantages. Another important aspect in structure preservation is the design of the electrode array. Two different designs are used: a “straight” lateral wall lying electrode array (LW) or a “pre-curved” perimodiolar lying electrode array (PM). Interestingly, until now, the best surgical approach and design of the implant is uncertain. Our hypothesis is that there is a difference in hearing preservation outcomes between the four possible treatment options. Methods We designed a monocenter, multi-arm, randomized controlled trial to compare insertion trauma between four groups of patients, with each group having a unique combination of an electrode array type (LW or PM) and surgical approach (RW or CO). In total, 48 patients will be randomized into one of these four intervention groups. Our primary objective is the comparison of postoperative hearing preservation between these four groups. Secondly, we aim to assess structure preservation (i.e., scalar translocation, with basilar membrane disruption or tip fold-over of array) for each group. Thirdly, we will compare objective outcomes of hearing and structure preservation by way of electrocochleography (ECochG). Discussion Cochlear implantation by way of a cochleostomy or round window approach, using different electrode array types, is the standard medical care for patients with severe to profound bilateral sensorineural hearing loss, as it is a relatively simple and low-risk procedure that greatly benefits patients. However, loss of residual hearing remains a problem. This trial is the first randomized controlled trial that evaluates the effect of cochlear insertion trauma of several CI treatment options on hearing preservation. Trial registration Netherlands Trial Register (NTR) NL8586 . Registered on 4 May 2020. Retrospectively registered; 3/48 participants were included before registration.

Published

2021

48. Research on a Non-Contact Multi-Electrode Voltage Sensor and Signal Processing Algorithm.

Author

Zhang, Wenbin, Yang, Yonglong, Zhao, Jingjing, Huang, Rujin, Cheng, Kang, and He, Mingxing

Subjects

*SIGNAL processing, *ELECTRIC field strength, *POSITION sensors, *DETECTORS, *ELECTRIC potential measurement, *CONTACT mechanics, *ELECTRIC capacity

Abstract

Traditional contact voltage measurement requires a direct electrical connection to the system, which is not easy to install and maintain. The voltage measurement based on the electric field coupling plate capacitance structure does not need to be in contact with the measured object or the ground, which can avoid the above problems. However, most of the existing flat-plate structure voltage measurement sensors are not only expensive to manufacture, but also bulky, and when the relative position between the wire under test and the sensor changes, it will bring great measurement errors, making it difficult to meet actual needs. Aiming to address the above problems, this paper proposes a multi-electrode array structure non-contact voltage sensor and signal processing algorithm. The sensor is manufactured by the PCB process, which effectively reduces the manufacturing cost and process difficulty. The experimental and simulation results show that, when the relative position of the wire and the sensor is offset by 10 mm in the 45° direction, the relative error of the traditional single-electrode voltage sensor is 17.62%, while the relative error of the multi-electrode voltage sensor designed in this paper is only 0.38%. In addition, the ratio error of the sensor under the condition of power frequency of 50 Hz is less than ±1% and the phase difference is less than 4°. The experimental results show that the sensor has good accuracy and linearity. [ABSTRACT FROM AUTHOR]

Published

2022

49. Actively Multiplexed μECoG Brain Implant System With Incremental-ΔΣ ADCs Employing Bulk-DACs.

Author

Huang, Xiaohua, Londono-Ramirez, Horacio, Ballini, Marco, Van Hoof, Chris, Genoe, Jan, Haesler, Sebastian, Gielen, Georges, Helleputte, Nick Van, and Lopez, Carolina Mora

Subjects

DIGITAL-to-analog converters, MULTIPLEXING, THIN film transistors, CMOS integrated circuits, SPATIAL resolution, INTEGRATED circuits

Abstract

Fundamental neuroscience research and high-performance neuro-prostheses require large-scale brain interfaces with ever-greater spatial resolution across a large cortex coverage, which cannot be achieved with current passive (micro) electrocorticography (ECoG) technologies. In this article, we present an active micro-electrocorticography ($\mu $ ECoG) implant system that circumvents these challenges while achieving significantly lower noise compared to other existing active $\mu $ ECoG arrays. The proposed brain implant system is composed of a flexible, actively multiplexed 256-electrode $\mu $ ECoG array and an incremental- $\Delta \Sigma $ readout integrated circuit (ROIC). The 1 cm $\times $ 1 cm $\mu $ ECoG array was fabricated in a 3- $\mu \text{m}$ IGZO thin-film transistor (TFT) technology on a 15- $\mu \text{m}$ flexible foil and coupled to a 1.25 mm $\times $ 1.25 mm CMOS ROIC fabricated in a 22-nm fully depleted silicon on insulator (FDSOI) process. Due to the 256:16 time-division multiplexing achieved in the electrode array, only 16 multiplexed channels are required in the ROIC to acquire signals from the 256 electrodes simultaneously. By combining TFT multiplexing with newly proposed bulk-DAC (BDAC) feedback in the readout channel, we can integrate and address 4 $\times $ more electrodes than other passive arrays, achieve >10 $\times $ less noise than existing active arrays, and obtain >2 $\times $ effective channel area reduction in the ROIC while maintaining comparable electrical performance over current state-of-the-art ($\mu $)ECoG readouts. [ABSTRACT FROM AUTHOR]

Published

2022

50. Multi-objective Optimization of Non-invasive Voltage Sensor Considering Sensitivity, Array Arrangement, and Cost.

Author

Qi Qian, Liang Shu, Linghao Wang, and Zhizhou Bao

Subjects

VOLTAGE, DETECTORS, SENSOR arrays, REGRESSION analysis, COST

Abstract

Non-invasive sensors are designed to offer ease of installation and avoid contact with dangerous hot wires. To optimize the array design of sensors, a multi-objective optimization method considering sensitivity, array arrangement, and cost is proposed in this study. The total array induced charge Q and the location sensitivity S1 are established to evaluate the sensor performance. On the basis of these evaluation indexes, design criteria for the array arrangement are proposed, which include the electrode shape, the array profile, and the space interval angle between electrode elements. Following this design basis, two objective functions for the array design are investigated. The first objective function is based on the entropy-CRITIC weight of the two regression models and the second objective function is based on the manufacturing cost. For the multi-objective design, the NAGA-II algorithm is employed and the VIKOR strategy is used to select the decision from the Pareto set. Optimization results show that, compared with the original design, the value of the first objective function is improved by 74.35% and the value of the second objective function is reduced by 22.99%. It is found that the rectangular shape is suitable for the single-electrode element design. The sensing array is best designed in a ring profile, and the optimal number of electrodes is 3. [ABSTRACT FROM AUTHOR]

Published

2022